PFAS, or perfluoroalkyl and polyfluoroalkyl substances, are a group of manmade chemicals used across many facets of our lives. Since the 1940s, PFAS have been commercialized and universally valued in product manufacturing. After their initial use in non-stick and protective coatings, PFAS use spread across many sectors, including personal care products, food packaging, clothing, firefighting foam, pesticides, paints and solvents, cover textiles, and more. Health concerns about specific PFAS (such as PFOS and PFOA) have prompted manufacturers to transition to other PFAS chemicals.

But the same properties that make PFAS so attractive for consumer and commercial use also contribute to potential exposure and human health risks. PFAS are made up of chains of carbon and fluorine atoms. The carbon-fluorine bond is arguably the strongest chemical bond in nature.

Data show that approximately 97% of Americans have detectable levels of PFAS in their blood, but we do not fully understand how exposures occur or their potential health consequences. Limited studies have linked PFAS exposure to:

• Altered fetal development
• Impaired cognitive ability in young children
• Negative effects on reproductive health
• Immune system disorders
• Prostate, kidney, and testicular cancers

Chemical Insights Research Institute (CIRI), in partnership with Emory University’s Rollins School of Public Health, is conducting a multi-phase research study that will provide key insights into human exposure risks and toxicological outcomes from the use of certain performance textiles, including:

• Develop methods for identifying and quantifying PFAS in the textiles,
• Acquire baseline data on PFAS in the textiles,
• Evaluate and compare PFAS release from the textiles, and
• Explore the parameters that influence PFAS exposure levels during use.

To conduct this research, CIRI is utilizing their state-of-the-art human exposure chambers and specialty equipment and techniques to evaluate possible exposure from use of the textiles. They are studying the potential inhalation of PFAS in the air, ingestion of PFAS in settled dust around the textile, and exposure from dermal, or skin, transfer.

Specific PFAS identified and their levels varied across consumer brands. Within a given textile material, PFAS levels also varied, indicating that PFAS are not uniformly distributed within the material.

The next phase of this research will expand to include how textile use and age can lead to potential dermal exposure, skin migration, and ingestion.